Data write control apparatus and method

ABSTRACT

In a data write control method, a write control apparatus currently runs a program in a write-back mode in which data are written to a volatile memory. When the apparatus detects that a quantity of dirty blocks in the volatile memory has reached a threshold, it predicts a first amount of execution progress of the program within a prediction time period under an assumption of the apparatus being in a write-through mode in which data are written to the volatile memory and a non-volatile memory. The apparatus also predicts a second amount of execution progress of the program within the prediction time period under an assumption of the apparatus being in the write-back mode. When the predicted first amount of execution progress exceeds the predicted second amount of execution progress, the apparatus switches from the write-back mode to the write-through mode.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No. 15/696,416, filed on Sep. 6, 2017, which is a continuation of International Application No. PCT/CN2016/074045, filed on Feb. 18, 2016, which claims priority to Chinese Patent Application No. 201510101154.4, filed on Mar. 6, 2015. All of the aforementioned patent applications are hereby incorporated by reference in their entirety.

TECHNICAL FIELD

The present application relates to the field of data write control technologies, and in particular, to a data write control apparatus and method.

BACKGROUND

A nonvolatile static random access memory (NV-SRAM) is a storage structure including both an static random access memory (SRAM) and a non-volatile memory (NVM). In a working mode, an electronic apparatus stores data using an SRAM. After the electronic apparatus encounters a power failure, an NV-SRAM can back up data to an NVM unit. However, after the electronic apparatus encounters a power failure, the nonvolatile SRAM needs to be powered by a relatively large on-chip energy storage capacitor, so as to perform data backup. The capacitor may cause relatively high overheads of a chip area and costs. If a relative small on-chip energy storage capacitor is used, backup may fail due to insufficient electric energy. After the backup fails, a previous successful backup point needs to be rolled back to. Rolling back to the previous backup point causes some performance overheads, thereby affecting execution progress of a program.

SUMMARY

Embodiments of the present application provide a data write control apparatus and method, so that the program execution efficiency of the write apparatus and method is improved by switching between two different write modes.

A first aspect of the embodiments of the present application provides a data write control apparatus, including a first memory, a second memory, and a processor, where the first memory includes a volatile storage unit, the second memory is a nonvolatile storage unit, and a data write mode of the data write control apparatus includes a write-back mode and a write-through mode; and in write-back mode, the processor writes received data to the first memory, and in write-through mode, the processor writes received data to the first memory and the second memory; when the write control apparatus is in write-back mode, the processor detects a quantity of dirty blocks in the first memory; when the quantity of dirty blocks reaches a first preset threshold, separately predicts execution progress of a program run by the processor within a danger time period in the two write modes; and when it is predicted that the execution progress of the program run by the processor within the danger time period in write-through mode is faster than the execution progress of the program run by the processor within the danger time period in write-back mode, switches a current data write mode to the write-through mode; and when the write control apparatus is in write-through mode, the processor detects the quantity of dirty blocks; and when the quantity of dirty blocks decreases to a second preset threshold, switches the current data write mode to the write-back mode.

Further, according to the first aspect of the embodiments of the present application, the first memory further includes a nonvolatile storage unit; after the data write control apparatus encounters a power failure, data in the volatile storage unit is backed up to the nonvolatile storage unit; and the first preset threshold is a maximum quantity of dirty blocks that can be backed up by the first memory.

Further, according to the first aspect of the embodiments of the present application, a calculation formula for predicting the execution progress of the program of the write control apparatus when the write-back mode is used is:

${E\left( {G - R} \right)} = {{k\left( {L - t_{s} - \frac{1}{\lambda}} \right)} + {{ke}^{{- \lambda}\; L}\left( {t_{s} + \frac{1}{\lambda} + L} \right)}}$

where k is the execution progress of the program run by the processor within a unit time in write-back mode; L is a length of the preset danger time period; if a time when the quantity of dirty blocks reaches the first preset threshold is used as a zero time, t_(s) is a time of latest power supply before the zero time; and 1/λ is an average power supply time of the data write control apparatus that is pre-obtained by means of statistics collection; and a calculation formula for predicting the execution progress of the program of the write control apparatus when the write-through mode is used is:

E(G′)=k′L

where k′ is the execution progress of the program run by the processor within a unit time in write-through mode.

Further, according to the first aspect of the embodiments of the present application, the second preset threshold equals the first preset threshold minus 1.

A second aspect of the embodiments of the present application provides a data write control method applied in the data write control apparatus, where the data write control apparatus includes a first memory, a second memory, and a processor, the first memory includes a volatile storage unit, the second memory is a nonvolatile storage unit, and a data write mode of the data write control apparatus includes a write-back mode and a write-through mode; and in write-back mode, the processor writes received data to the first memory, in write-through mode, the processor writes received data to the first memory and the second memory; and the method includes, when the write control apparatus is in write-back mode, detecting, by the processor, a quantity of dirty blocks in the first memory; when the quantity of dirty blocks reaches a first preset threshold, separately predicting execution progress of a program run by the processor within a danger time period in the two write modes; when it is predicted that the execution progress of the program run by the processor within the danger time period in write-through mode is faster than the execution progress of the program run by the processor within the danger time period in write-back mode, switching a current data write mode to the write-through mode; and when the write control apparatus is in write-through mode, detecting the quantity of dirty blocks; and when the quantity of dirty blocks decreases to a second preset threshold, switching the current data write mode to the write-back mode.

Further, according to the second aspect of the embodiments of the present application, the first memory further includes a nonvolatile storage unit; after the data write control apparatus encounters a power failure, data in the volatile storage unit is backed up to the nonvolatile storage unit; and the first preset threshold is a maximum quantity of dirty blocks that can be backed up by the first memory.

Further, according to the second aspect of the embodiments of the present application, a calculation formula for predicting the execution progress of the program of the write control apparatus when the write-back mode is used is:

${E\left( {G - R} \right)} = {{k\left( {L - t_{s} - \frac{1}{\lambda}} \right)} + {{ke}^{{- \lambda}\; L}\left( {t_{s} + \frac{1}{\lambda} + L} \right)}}$

where k is the execution progress of the program run by the processor within a unit time in write-back mode; L is a length of the preset danger time period; if a time when the quantity of dirty blocks reaches the first preset threshold is used as a zero time, t_(s) is a time when power is supplied to the data write control apparatus within the danger time period; and 1/λ is an average power supply time of the data write control apparatus that is pre-obtained by means of statistics collection; and a calculation formula for predicting the execution progress of the program of the write control apparatus when the write-through mode is used is:

E(G′)=k′L

where k′ is the execution progress of the program run by the processor within a unit time in write-through mode.

Further, according to the second aspect of the embodiments of the present application, the second preset threshold equals the first preset threshold minus 1.

As can be seen, according to the data write control apparatus and method in the embodiments of the present application, when a data write mode of the data write control apparatus is a write-back mode, a quantity of dirty blocks in a volatile storage unit is detected. When the quantity of dirty blocks reaches a preset threshold, it is determined according to a preset condition whether to switch the data write mode of the data write control apparatus to a write-through mode. When the preset condition is satisfied and the data write mode the data write control apparatus is switched to the write-through mode, the quantity of dirty blocks continues to be detected. When the quantity of dirty blocks is less than a second preset threshold, the data write mode of the data write control apparatus is switched to the write-back mode. In this way, execution performance of a program of the data write control apparatus can be improved.

BRIEF DESCRIPTION OF DRAWINGS

To describe the technical solutions in the embodiments of the present application more clearly, the following briefly describes the accompanying drawings required for describing the embodiments or the prior art. The accompanying drawings in the following description show merely some embodiments of the present application, and a person of ordinary skill in the art may still derive other drawings from these accompanying drawings without creative efforts.

FIG. 1 is a structural diagram of a data write apparatus according to a first embodiment of the present application;

FIG. 2 is a schematic diagram of switching between two data write modes of the data write apparatus; and

FIG. 3 is a flowchart of a data write method according to a second embodiment.

DESCRIPTION OF EMBODIMENTS

The following clearly describes the technical solutions in the embodiments of the present application with reference to the accompanying drawings in the embodiments of the present application. The described embodiments are merely some but not all of the embodiments of the present application. All other embodiments obtained by a person of ordinary skill in the art based on the embodiments of the present application without creative efforts shall fall within the protection scope of the present application.

Technical solutions provided in the embodiments of the present application are mainly applied in a memory that has both a nonvolatile storage unit and a volatile storage unit, for example, a NV-SRAM. When an electronic apparatus using a memory of this structure as an internal memory encounters a power failure, power may be supplied to the memory using a backup power source on the memory, so that data in the volatile storage unit is backed up to the nonvolatile storage unit. For ease of description, the present application is described using the NV-SRAM as an example in the following embodiments. It should be noted that the memory applied in the present application is not limited to the NV-SRAM, and another memory having the same structure is also within the scope disclosed in the present application.

The volatile storage unit in NV-SRAM is a SRAM, the nonvolatile storage unit is a phase-change random access memory (PCM), and the backup power source is an on-chip energy storage capacitor.

The technical solutions provided in the present application are described from different perspectives using different embodiments below.

First Embodiment

The first embodiment provides a data write control apparatus 10. The data write control apparatus 10 includes a first memory 11, a second memory 12, and a processor 13. The first memory 11 includes a volatile storage unit 111 and a nonvolatile storage unit 112. The second memory 12 is a nonvolatile storage unit.

The write control apparatus 10 includes two data write modes, that is, a write-back mode and a write-through mode. In write-back mode, data in a received data write request is written to the first memory. In write-through ( ) mode, data in a received data write request is written to both the first memory 11 and the second memory 12.

In this embodiment, the first memory 11 is a NV-SRAM; the volatile storage unit 111 is a SRAM; and the nonvolatile storage unit 112 is a PCM. After the data write control apparatus 10 encounters a power failure, power may be supplied to the first memory 11 using a backup power source 113 on the first memory 11, so that data in the volatile storage unit 111 is backed up to the nonvolatile storage unit 112.

In write-back mode, when receiving a data write instruction, the processor 13 directly writes data to a storage block in the volatile storage unit 111. The data written to the volatile storage unit 111 is written to the second memory 12 only when the data needs to be replaced in the volatile storage unit 111. A storage block that is written to the volatile storage unit 111 but is not written to the second memory 12 is a dirty block. Each storage block has a dirty block tag, which is used to identify whether the storage block is a dirty block. The volatile storage unit 111 has relatively high data read and write speeds. Therefore, in write-back mode, the data write control apparatus 10 has faster program processing progress. When the data write control apparatus 10 encounters a power failure, data in all dirty blocks in the volatile storage unit 111 needs to be backed up to the nonvolatile storage unit 112. However, because electric energy of the backup power source 113 is limited, when a quantity of dirty blocks exceeds a quantity of dirty blocks whose backup is supported by the backup power source 113, the backup fails. When the backup fails, a program needs to be rolled back to a previous successful backup point. This causes high performance overheads, thereby affecting execution progress of the program.

In write-through mode, when receiving a data write instruction, the processor 13 also writes data to the second memory 12 when writing the data to the storage block of the volatile storage unit 111. In this way, no dirty block is generated. Therefore, no backup failure occurs. However, speeds of reading and writing data by the nonvolatile storage unit 112 are relatively low. Therefore, compared with the write-back mode, in write-through mode, the data write control apparatus 10 has relatively slow program processing progress.

Therefore, to improve performance of the data write control apparatus 10, the data write control apparatus 10 provided in this embodiment may be switched between the two data write modes, thereby improving the overall program processing progress.

When the write control apparatus 10 is in write-back mode, the processor 13 detects a quantity of dirty blocks in the first memory 11; when the quantity of dirty blocks reaches a first preset threshold, predicts execution progress of a program in the two write modes; and when it is predicted that the execution progress in write-through mode is faster than the execution progress in write-back mode, switches a current data write mode to the write-through mode.

When the write control apparatus 10 is in write-through mode, the processor 13 detects the quantity of dirty blocks; and when the quantity of dirty blocks reaches a second preset threshold, switches the current data write mode to the write-back mode.

The first preset threshold is a maximum quantity of dirty blocks that can be backed up by the first memory 11.

In this embodiment, in an implementation manner, when the quantity of dirty blocks detected by the processor 13 reaches the first preset threshold, the current data write mode is switched to the write-through mode.

In another implementation manner, when the quantity of dirty blocks detected by the processor 13 reaches the first preset threshold, the execution progress of the program in the two write modes is predicted. In this case, the predicted execution progress of the program is execution progress of the program within a danger time period L that is from a time when the quantity of dirty blocks reaches the first preset threshold to a time when the quantity of dirty blocks is less than the first preset threshold.

The data write control apparatus 10 in this embodiment is usually a particular detection apparatus, for example, a sensor used for detecting a health status of a human body in a wearable device. Therefore, only one particular program is usually run. The danger time period L in which a quantity of dirty blocks of the running program reaches and is greater than the first preset threshold is basically the same. Therefore, for the particular program, the danger time period L may be obtained in advance.

In this embodiment, execution progress of a program may be represented using a percentage. The data write control apparatus 10 runs the particular program. Therefore, a total quantity of instructions of the program is definite. The execution progress of the program may be calculated according to Formula (1):

$\begin{matrix} {{G(t)} = \frac{N_{executed}(t)}{N_{total}}} & (1) \end{matrix}$

where N_(executed)(t) is a quantity of instructions that have been executed, and N_(total) is the total quantity of instructions; and if time overheads caused by pipeline stall are ignored, it may be approximately considered that G (t) linearly increases.

First, the progress of the program is calculated when the write-back mode is used within the danger time period L.

As shown in FIG. 2, a curve C1 is a progress curve of the program when the write-back mode is used, and a curve C2 is a progress curve of the program when the write-through mode is used.

After the program starts running, the data write control apparatus 10 writes data in write-back mode, starts detecting the quantity of dirty blocks; and when the quantity of dirty blocks reaches the first preset threshold, obtains the preset danger time period L, and predicts processing progress of the program in the two write modes in the time period L.

When the quantity of dirty blocks reaches the first preset threshold, and the write-back mode is not switched to the write-through mode, a process for calculating the processing progress of the executed program is as follows.

First, a power failure probability of the data write control apparatus 10 is calculated. In actual application, a power failure may occur in different situations. For example, if the data write control apparatus 10 uses a solar power system, a passive power failure occurs when sun is blocked, the sun angle changes, the weather changes, or the like. This feature is represented as memory lessness of a power supply time in terms of a power supply feature, that is, power supply time lengths are not directly associated with one another. Therefore, modeling may be performed on a power supply time by means of exponential distribution:

$\begin{matrix} {{f\left( t_{on} \right)} = \left\{ \begin{matrix} {\lambda \; e^{{- \lambda}\; t_{on}}} & {{{if}\mspace{14mu} t_{on}} \geq 0} \\ {0\mspace{59mu}} & {{{if}\mspace{14mu} t_{on}} < 0} \end{matrix} \right.} & (2) \end{matrix}$

where f(t_(on)) is a probability density of the power supply time length, and

$\frac{1}{\lambda}$

is a mathematical expectation of the power supply time length.

Then, a formula for calculating a probability that a power failure occurs within the danger time period L is:

P(F)=P(t _(on) <L)=∫₀ ^(L) f(t _(on))dt _(on)=1−e ^(−λL)  (3)

For a continuous power supply time t, formulas for calculating progress percentages when the two modes are used are respectively:

G(t)=kt

G′(t)=k′t

where k is a program progress within a unit time when the write-back mode is used, and k′ is a program progress within a unit time when the write-through mode is used.

If a power failure occurs within the danger time period L, a backup failure occurs, and after backup fails, backup rollback occurs. As shown in FIG. 2, if a power failure occurs at a time Te, a backup failure occurs, and the program needs to be rolled back to a program progress at a time Ts when this power supply starts. If a start point of the danger time period L, that is, a switching point P, is used as a zero time, progress of the rolled-back program is:

$\begin{matrix} {{R\left( t_{e} \right)} = \left\{ \begin{matrix} {G\left( {t_{e} + t_{s}} \right)} & {{{if}\mspace{14mu} t_{c}} < L} \\ {0\mspace{85mu}} & {{{if}\mspace{14mu} t_{c}} > L} \end{matrix} \right.} & (4) \end{matrix}$

where Te<L represents that a power failure occurs within the danger time period L; and Te>L represents that no power failure occurs within the danger time period L, and the program does not need to be rolled back.

Therefore, if the write-back mode is not switched to the write-through mode at the switching point within the danger time period L, a formula for calculating an expectation of an actual progress percentage G-R is:

$\begin{matrix} {{E\left( {G - R} \right)} = {{{G(L)} - {\int_{0}^{L}{{k\left( {t_{e} + t_{s}} \right)}{f\left( t_{e} \right)}{dt}_{e}}}} = {{k\left( {L - \frac{1}{\lambda} - t_{s}} \right)} + {{ke}^{{- \lambda}\; L}\left( {L + \frac{1}{\lambda} + t_{s}} \right)}}}} & (6) \end{matrix}$

If the quantity of dirty blocks reaches the first preset threshold, the data write mode is switched to the write-through mode at the switching point, and a formula for calculating an expectation of the actual progress percentage G-R is:

E(G′)=k′L  (7)

The data write mode is switched to the write-through mode only when E (G-R)<E (G′), that is:

$\begin{matrix} {{{E\left( {G - R} \right)} - {E\left( G^{\prime} \right)}} = {{{k\left( {L - t_{s} - \frac{1}{\lambda}} \right)} + {{ke}^{{- \lambda}\; L}\left( {t_{s} + \frac{1}{\lambda} + L} \right)} - {k^{\prime}L}} < 0}} & (8) \end{matrix}$

It may be obtained by transforming Formula (8) that:

$\frac{k}{k^{\prime}} < \frac{\lambda \; L}{{\lambda \; L} - 1 - {\lambda \; t_{s}} + {e^{{- \lambda}\; L}\left( {1 + {\lambda \; L} + {\lambda \; t_{s}}} \right)}}$

That is, when the foregoing formula is satisfied, the data write mode of the data write control apparatus 10 is switched to the write-through mode.

After the write-through mode is entered, the quantity of dirty blocks no longer increases. However, because new data is written, data in original dirty blocks are replaced and written to the second memory 12. In this way, the quantity of dirty blocks decreases. When the quantity of dirty blocks decreases to the second preset threshold, the processor 13 switches the data write mode of the data write control apparatus 10 to the write-through mode.

Program execution performance in write-back mode is relatively high. Therefore, the second preset threshold preferably equals the first preset threshold minus 1. In this way, the data write control apparatus 10 may quickly enter the write-back mode. Certainly, in another embodiment, different second preset thresholds may be set according to a specific situation.

Second Embodiment

The second embodiment provides a data write method applied in the data write apparatus provided in the first embodiment. As shown in FIG. 3, FIG. 3 is a flowchart of the data write method.

Step S301: When the write control apparatus is in write-back mode, the processor detects a quantity of dirty blocks in the first memory.

Step S302: When the quantity of dirty blocks reaches a first preset threshold, separately predict execution progress of a program run by the processor within a danger time period in two write modes.

Step S303: When it is predicted that the execution progress of the program run by the processor within the danger time period in write-through mode is faster than the execution progress of the program run by the processor within the danger time period in write-back mode, switch a current data write mode to the write-through mode.

Step S304: When the write control apparatus is in write-through mode, detect the quantity of dirty blocks; and when the quantity of dirty blocks reaches a second preset threshold, switch the current data write mode to the write-back mode.

In this embodiment, the first memory further includes the nonvolatile storage unit. After the data write control apparatus encounters a power failure, data in the volatile storage unit is backed up to the nonvolatile storage unit, and the first preset threshold is a maximum quantity of dirty blocks that can be backed up by the first memory.

In this embodiment, a calculation formula for predicting the execution progress of the program of the write control apparatus when the write-back mode is used is:

${E\left( {G - R} \right)} = {{k\left( {L - t_{s} - \frac{1}{\lambda}} \right)} + {{ke}^{{- \lambda}\; L}\left( {t_{s} + \frac{1}{\lambda} + L} \right)}}$

where k is the execution progress of the program run by the processor within a unit time in write-back mode; L is a length of the preset danger time period; if a time when the quantity of dirty blocks reaches the first preset threshold is used as a zero time, t_(s) is a time when power is supplied to the data write control apparatus within the danger time period; and 1/λ is an average power supply time of the data write control apparatus that is pre-obtained by means of statistics collection.

A calculation formula for predicting the execution progress of the program of the write control apparatus when the write-through mode is used is:

E(G′)=k′L

where k′ is the execution progress of the program run by the processor within a unit time in write-through mode.

In this embodiment, the second preset threshold equals the first preset threshold minus 1.

A person of ordinary skill in the art may understand that all or a part of the steps of the methods in the embodiments may be implemented by a program instructing relevant hardware. The program may be stored in a computer readable storage medium. The storage medium may include a read-only memory (ROM), a random access memory (RAM), a magnetic disk, or an optical disc.

The data write apparatus and method provided in the embodiments of the present application are described in detail above. In this specification, specific examples are used to describe the principle and implementation manners of the present application, and the description of the embodiments is only intended to help understand the method and core idea of the present application. In addition, a person of ordinary skill in the art may, based on the idea of the present application, make modifications with respect to the specific implementation manners and the application scope. Therefore, the content of this specification shall not be construed as a limitation to the present application. 

What is claimed is:
 1. A data write control apparatus, comprising: a first memory comprising a volatile storage unit; a second memory comprising a first nonvolatile storage unit; and a processor coupled to the first memory and the second memory and executing a program, the processor having a write-back mode in which received data are written to the first memory, and a write-through mode in which received data are written to the first memory and the second memory, and the processor being configured to: detect, while in the write-back mode, that a quantity of dirty blocks in the first memory has reached a first preset threshold; in response to detecting that the quantity of dirty blocks in the first memory has reached the first preset threshold, predict a first amount of execution progress of the program within a prediction time period under an assumption of operating in the write-through mode, and predict a second amount of execution progress of the program within the prediction time period under an assumption of operating in the write-back mode; and when the first amount of execution progress exceeds the second amount of execution progress, switch from the write-back mode to the write-through mode.
 2. The data write control apparatus according to claim 1, wherein the processor is further configured to: detect the quantity of dirty blocks while in the write-through mode; and switch from the write-through mode to the write-back mode when the quantity of dirty blocks decreases to a second preset threshold.
 3. The data write control apparatus according to claim 2, wherein the second preset threshold equals the first preset threshold minus one.
 4. The data write control apparatus according to claim 1, wherein the first memory further comprises a second nonvolatile storage unit, wherein the processor is configured to back up data in the volatile storage unit of the first memory to the second nonvolatile storage unit upon encountering a power failure of an external power supply.
 5. The data write control apparatus according to claim 1, wherein the processor predicts the second amount of execution progress according to: ${{E\left( {G - R} \right)} = {{k\left( {L - t_{s} - \frac{1}{\lambda}} \right)} + {{ke}^{{- \lambda}\; L}\left( {t_{s} + \frac{1}{\lambda} + L} \right)}}},$ wherein G is an amount of the execution progress of the program with a resumption of the program being without rolling back, R is an amount of rolling back progress of the program when the power failed within the prediction time period, k is an amount of execution progress of the program within a unit time when the apparatus is in the write-through mode, wherein L is a length of the prediction time period, wherein t_(s) is a time of latest power supply before a zero time, which is a time when the quantity of dirty blocks reaches the first preset threshold, and wherein 1/λ is an average power supply time of the apparatus, and wherein the processor predicts the first amount of execution progress according to: E(G′)=k′L, wherein G′ is an amount of execution progress of the program, k′ is the execution progress of the program run by the processor within a unit time when the apparatus is in write-through mode.
 6. A data write control method performed by an apparatus having a first memory comprising a volatile storage unit and a second memory comprising a nonvolatile storage unit, wherein the apparatus runs a program and has a write-back mode in which received data are written to the first memory and a write-through mode in which received data are written to the first memory and the second memory, the method comprising: detecting, when the apparatus is in the write-back mode, that a quantity of dirty blocks in a first memory has reached a first preset threshold; in response to detecting that the quantity of dirty blocks in the first memory has reached the first preset threshold, predicting a first amount of execution progress of the program within a prediction time period under an assumption of the apparatus being in the write-through mode, and predicting a second amount of execution progress within the prediction time period under an assumption of the apparatus being in the write-back mode; when the amount of the first execution progress exceeds the amount of the second execution progress, switching from the write-back mode to the write-through mode.
 7. The data write control method according to claim 6, further comprising: detecting the quantity of dirty blocks when the apparatus is in the write-through mode; and switching from the write-through mode to the write-back mode when the quantity of dirty blocks decreases to a second preset threshold.
 8. The data write control method according to claim 7, wherein the second preset threshold equals the first preset threshold minus
 1. 9. The data write control method according to claim 6, wherein the first memory further comprises a second nonvolatile storage unit, and the method further comprises: detecting a power failure; upon detecting the power failure, backing up data in the volatile storage unit of the first memory to the second nonvolatile storage unit, and wherein the first preset threshold corresponds to a backup capacity of the first memory.
 10. The data write control method according to claim 6, wherein the predicting of the second amount execution progress is according to: ${{E\left( {G - R} \right)} = {{k\left( {L - t_{s} - \frac{1}{\lambda}} \right)} + {{ke}^{{- \lambda}\; L}\left( {t_{s} + \frac{1}{\lambda} + L} \right)}}},$ wherein G is an amount of the execution progress of the program with an assumption of the program being without rolling back, R is an amount of rolling back progress of the program when the power failed within the prediction time period, k is an amount of execution progress of the program within a unit time when the apparatus is in write-through mode, wherein L is a length of the prediction time period, wherein t_(s) is a time of latest power supply before a zero time, which is a time when the quantity of dirty blocks reaches the first preset threshold, and wherein 1/λ is an average power supply time of the apparatus, and wherein the predicting of the first amount of the execution progress is according to: E(G′)=k′L wherein G′ is an amount of execution progress of the program, k′ is the execution progress of the program run by the processor within a unit time when the apparatus is in write-through mode. 